open FORD KUGA 2011 1.G Repair Manual

Accessory Drive
Inspection and Verification
1. Verify the customer concern.
2. Visually inspect for obvious signs of mechanicaldamage.
Visual Inspection Chart
Mechanical
– Damaged or contaminated accessory drive belt or air conditioning (A/C) compressor belt
– Damaged or contaminated pulley(s)
– Incorrect accessory drive belt or A/C compressor belt
– Incorrect fitment of the accessory drive belt or A/C compressor belt
– Accessory drive belt tensioner
– Accessory drive belt idler pulley
– Generator
– A/C compressor
– A/C compressor belt tensioner
– Pulley(s)
– Loose hardware
3. If an obvious cause for an observed or reported concern is found, correct the cause (if possible)
before proceeding to the next step.
Accessory Drive Belt Concerns
CAUTION: Do not lubricate the accessory
drive belt, accessory drive belt tensioner(s)
or idler pulley(s) as potential damage to
the accessory drive belt material
construction, accessory drive belt
tensioner damping mechanism, accessory
drive belt tensioner pulley bearing and idler
pulley(s) bearing may occur.
NOTE: All the diagnosis and testing information
contained within this procedure can be used for
the accessory drive belt and the A/C compressor
belt.
Cracking
Accessory drive belts are made from rubber which
hardens with time and can develop cracks. As the
accessory drive belt runs on the back of some of
the pulleys, the cracks are opened up. Small cracks
are not considered to be a failure of the accessory drive belt. Only if the crack is deep enough to reach
the bottom of the groove to expose the cord or any
chunks are found to be missing from the accessory
drive belt, is the accessory drive belt condition
considered to be unacceptable.
1. Check the accessory drive belt for cracks. If the
damage exceeds the acceptable limit, install a
new accessory drive belt.
REFER to: Accessory Drive Belt (303-05
Accessory Drive - 2.5L Duratec
(147kW/200PS) - VI5, Removal and
Installation).
and/or
REFER to: Air Conditioning (A/C) Compressor
Belt (303-05 Accessory Drive - 2.5L Duratec
(147kW/200PS) - VI5, Removal and
Installation).
Chunking
Chunking describes the condition where long
lengths of rubber become detached from the ribs
of the accessory drive belt. This is considered to
be a failure of the accessory drive belt.
MPZ9632071
2. Check the accessory drive belt for damage. If any chunks are found to be missing, install a
new accessory drive belt.
REFER to: Accessory Drive Belt (303-05
Accessory Drive - 2.5L Duratec
(147kW/200PS) - VI5, Removal and
Installation).
and/or
REFER to: Air Conditioning (A/C) Compressor
Belt (303-05 Accessory Drive - 2.5L Duratec
(147kW/200PS) - VI5, Removal and
Installation).
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• Starting process
• Engine running– Fuel supply to the engine including lambdacontrol
– Ignition setting including knock control
– Idle speed control
– Boost pressure control
– Valve timing via the camshaft adjuster for the intake and exhaust camshafts (including
internal exhaust gas recirculation)
• Refrigerant compressor (activation, deactivation and delivery)
• EVAP purge valve
• Charging system
Fuel is supplied to the engine via a sequential
multi-point injection system. Ignition is performed
by a distributor-less ignition system with one
ignition coil unit for each cylinder.
The PCM optimizes engine power and emissions
at all times by processing the sensor signals and
information received via the CAN databus and
using these for open or closed loop control of the
different variables.
The PCM contains part of the PATS (passive
anti-theft system).
The PCM is supplied with battery voltage via a fuse
in the BJB (battery junction box). This power supply
is needed to ensure that saved data is not lost
when the engine is switched off.
For other power supply requirements, the PCM
switches on a relay in the BJB which is responsible
for supplying power to the PCM and to some
sensors and actuators. Each of these are protected
by fuses in the BJB.
To guarantee optimum engine running at all times,
the PCM has several adaptive (self-learning)
functions. These adapt the output signals to
changing circumstances, such as wear or system
faults.
In some cases a faulty signal is replaced with a
substitute value or limited. A substitute value can
be calculated from other signals or it can be
predefined by the PCM. The substitute value allows
the vehicle to keep on running without the emission
values changing unduly. Depending on the signal
failure, the PCM operates in emergency mode. In
this mode, the engine power and/or the engine
speed is reduced to prevent further damage.
Depending on the faulty signal, a fault code is
stored in the error memory of the PCM. These can be read out using IDS (Integrated Diagnostic
System) via the DLC.
The PCM processes and evaluates the signals
from the sensors. The following sensors send
signals to the PCM:
• CMP sensors
• CKP sensor
• MAF sensor
•KS
• ECT sensor
• TP sensor
• APP sensor
• Broadband HO2S
• Catalyst monitor sensor
• MAPT sensor
• Air conditioning (A/C) pressure sensor
• Alternator
• Fuel temperature and fuel pressure sensor
• Engine oil level, temperature and quality sensor
• Outside air temperature sensor
The following components receive signals from the
PCM:
• Powertrain Control Module relay
• A/C clutch relay
• injectors
• Direct ignition coils
• Cooling fan module
• Throttle control unit
• Camshaft adjuster solenoid valve
• Starter Relay
• EVAP purge valve
• Alternator
• Heating element - broadband HO2S
• Catalyst monitor sensor heating element
• FPDM
• Wastegate control valve
• Air conditioning compressor
The PCM receives the following signals via the
CAN databus:
• APP
•CPP
• BPP
• Vehicle speed.
• Refrigerant compressor request
• PAT S
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actuated) or opened (actuated). Each cylinder has
its own injector. The injection is accurately dosed
and takes place at a time determined by the PCM.
Injection takes place immediately in front of the
intake valves of the cylinder. The injectors are
actuated ground side via end-stages integrated
into the PCM and using the signal calculated by
the engine management system. Power is supplied
via the Powertrain Control Module relay in the BJB.
The injected fuel quantity depends on the opening
time, the fuel pressure and the diameter of the
nozzle holes.
The fuel metering is determined via open or
closed-loop control.
The open control loop differs from the closed
control loop in that the lambda control is
deactivated.
The PCM switches from closed to open-loop control
if the HO2S cools down to below 600°C or fails, as
well as when accelerating, coasting and at full load.
Regulation of injected fuel quantity via the PCM
involves:
• controlling the fuel pump,
• calculating the required quantity of fuel forengine starting,
• observance of the desired air/fuel ratio,
• calculating air mass,
• and calculating the fuel quantity for the different operating states and corresponding fuel
adjustment measures.
Open loop control
Open loop control is used primarily for fuel
injection, as long as the signals of the HO2S are
not involved in the calculation of the PCM.
The two most important reasons that make it
absolutely essential to run the engine without
lambda control (open-loop control) are the following
operating conditions:
• Cold engine (starting, warm-up phase)
• Full-load operation (WOT (wide open throttle))
Under these operating conditions the engine needs
a rich air/fuel mixture with lambda values below λ
= 1 in order to achieve optimum running or
optimum performance.
It is possible to keep this unregulated range very
small by using a broadband HO2S.
Closed-loop control
Closed loop control ensures strict control of
exhaust emissions in conjunction with the TWC (three-way catalytic converter) and economical fuel
consumption. With closed loop control, the signals
from the HO2S are analyzed by the PCM and the
engine always runs in the optimum range of λ = 1.
In addition to the normal HO2S, the signal from the
monitoring sensor for the catalytic converter is also
included in the control. The lambda control is
optimized on the basis of this data.
Certain factors such as wear, component
tolerances or more minor defects such as air leaks
in the intake system are compensated for by
lambda control. If the deviation occurs for a longer
period of time, this is recorded by the adaptive
(self-learning) function of lambda control. In this
instance, the entire map is shifted by the
corresponding amount, to enable control to
commence once again from the virtual baseline.
These adaptive settings are stored in the PCM and
are also used in open-loop control conditions.
If the adaptive value is too high or too low, an error
is stored in the fault memory of the PCM.
Oxygen sensor (HO2S) and catalyst monitor
sensor
A broadband HO2S is used as the HO2S. The
HO2S is located in front of the TWC. The catalyst
monitor sensor is located in the center of the TWC
so that it can detect any deterioration in the
cleaning performance of the TWC more quickly.
The HO2S measures the residual amount of
oxygen in the exhaust before the TWC.
The catalyst monitor sensor measures the amount
of oxygen in the exhaust gas after or in the TWC.
Both the HO2S and the catalyst monitor sensor
transmit these data to the PCM.
The broadband HO2S works at temperatures of
between 650°C and 900 °C. If the temperature
rises above 1000°C, the oxygen sensor will be
irreparably damaged.
To reach optimum operating temperature as quickly
as possible, an electrically-heated oxygen sensor
is installed. The heating also serves to maintain a
suitable operating temperature while coasting, for
example, when no hot gases are flowing past the
oxygen sensor.
The heating element in the HO2S is a PTC
(positive temperature coefficient) resistor. The
heating element is supplied with battery voltage as
soon as the Powertrain Control Module relay
engages. The HO2S is earthed via the PCM. As
the heating current is high when the element is
cold, it is limited via PWM in the PCM until a certain
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current value is reached. The PCM then
permanently connects the heating element to earth.
The catalyst monitor sensor is used by the PCM
to measure the oxygen content in the exhaust gas
in the TWC. If all the conditions for catalyst
diagnostics are met, based on this information the
PCM can check that the TWC is working
satisfactorily. The information is also used to
improve the air/fuel mixture adjustment.
The catalyst monitor sensor is similar in function
to an HO2S. The signal transmitted by the catalyst
monitor sensor changes sharply if the oxygen
content in the exhaust gas changes. For this
reason, catalyst monitor sensors are also called
"jump lambda sensors".
Fuel tank purging
The EVAP purge valve is only actuated by the PCM
if the coolant temperature is at least 60°C.
Actuation is done ground side by means of a PWM
signal. This makes it possible to have the full range
of opening widths, from fully closed to fully open.
The PCM determines from the operating conditions
when and how wide to open the EVAP tank purge
valve. If the EVAP purge valve is opened, the
engine sucks in ambient air through the activated
charcoal in the evaporative emission canister as
a result of the vacuum in the intake manifold. In
this way the adsorbed hydrocarbons are led to the
combustion chamber of the engine.
The EVAP tank purge valve is not actuated and
system cleaning is interrupted if the engine
switches to idle and/or a closed-loop control
process is initiated.
Power (battery voltage) is supplied via the
Powertrain Control Module relay in the BJB. The
solenoid coil resistance is between 17 and 24 ohms
at 20°C.
Engine speed control
The APP sensor provides the PCM with information
about the driver's request for acceleration.
The throttle control unit receives a corresponding
input signal from the PCM. An electric motor then
moves the throttle valve shaft by means of a set
of gears. The position of the throttle is continuously
recorded by the TP sensor. Information on throttle
position is processed and monitored by the PCM.
The TP sensor comprises two potentiometers.
These work in opposite ways to each other. In one
potentiometer, the resistance increases when the
throttle is opened, in the other it decreases. Thisallows the operation of the potentiometers to be
checked. The signal from the TP sensor is
amplified in the lower range (idle to a quarter open)
by the PCM to enable more precise control of the
throttle in this range. This is necessary because
the engine is very sensitive to changes in throttle
angle in this throttle opening range.
With the throttle valve position kept constant, the
ignition angle and the injected fuel quantity are
then varied to meet the torque demands.
Depending on the operating state of the engine, a
change in the position of the throttle flap may not
be necessary when the APP sensor changes.
If a fault develops in the throttle control unit, a
standby function is executed. This standby function
allows a slight opening of the throttle flap, so that
enough air passes through to allow limited engine
operation. For this purpose, there is a throttle flap
adjustment screw on the throttle housing. The
return spring closes the throttle flap until the stop
of the toothed segment touches the stop screw. In
this way a defined throttle flap gap is formed for
limp home mode.
The stop screw has a spring loaded pin, which
holds the throttle flap open for limp home mode.
In normal operating mode, this spring loaded pin
is pushed in by the force of the electric motor when
the throttle flap must be closed past the limp home
position (e.g. for idle speed control or overrun
shutoff).
Oil monitoring
The engine does not have an oil pressure
switch.
The oil level and oil quality are calculated.
Calculating the engine oil level
The oil level is determined by continuous
measurement of the capacitance (i.e. the ability to
store an electrical charge) between the two
capacitive elements of the engine oil
level/temperature/quality sensor. The different oil
levels cause the capacitance between the elements
to change. The data are recorded by the PCM and
converted into an oil level value. Temporary
fluctuations in oil level are automatically filtered out
by the PCM.
Calculating oil quality
The PCM calculates the oil quality from the oil level
measurement and the oil temperature measured
by the sensor, plus the engine speed and the
average fuel consumption. The driver is informed
about when an oil change is due.
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Calculation of valve timing adjustment
angle
The 2.5L Duratec (VI5) engine has two camshaft
adjustment units which work independently of each
other.
One camshaft adjustment solenoid is installed for
each intake camshaft and exhaust camshaft.
This allows the PCM to continuously adjust the
intake and exhaust-side camshaft adjustments
independently of one another. The timing is
adjusted by the PCM using curves; adjustment is
primarily done as a function of engine load and
engine speed.
In this way the engine performance is increased
and internal exhaust gas recirculation is realized.
The advantages of camshaft adjustment are as
follows:
• Higher torque and improved torquecharacteristics
• Reduced fuel consumption
• Improved emissions performance
The camshaft adjustment solenoids are actuated
by the PWM by means of a PCM signal.
Continuous adjustment of the camshafts by the
PCM is achieved by means of the camshaft
adjustment solenoids, the camshaft adjustment
units and two CMP sensors. A defined quantity of
engine is oil is supplied to or drained from the
adjustment units via the camshaft adjustment
solenoids. The existing EOP (engine oil pressure)
is taken into account in the process. In this way
the valve timings are adjusted according to the
operating condition of the engine. The camshaft
adjusters work according to the vane-cell principle.
On starting the engine, both camshafts are
mechanically locked in their starting positions. The
intake camshaft is in the maximum late position
and the exhaust camshaft in the maximum early
position.
Control is divided into four main areas:
• Low engine speed and low load
• Partial load
• Low engine speed and high load
• High engine speed and high load
At low engine speed and low load, the exhaust
valves open early and the intake valves open late.
The result is reduced fuel consumption and more
uniform idling. In the partial load range, the exhaust valves and
the intake valves open late. The late opening of
the exhaust valves results in a good utilization of
the expanding gases in the cylinder. Closing the
exhaust valves after Top Dead Center allows
internal exhaust gas recirculation through aspiration
of exhaust gases into the combustion chamber.
Moreover, the intake valves close after Bottom
Dead Centre, allowing the fresh air/fuel mixture
and exhaust gases to flow back into the intake
tract. The result is reduced fuel consumption and
low emissions.
At low engine speed and high engine load, the
exhaust valves open late and the intake valves
open early. Due to the resulting valve opening
overlap at Top Dead Centre, the pulsating gas
column within the combustion chamber is utilized
to achieve better charging of the combustion
chamber. The result is increased torque at lower
RPM.
At high engine speeds and high engine load, the
exhaust valves open early and the intake valves
close late. Because a rapid gas exchange must be
achieved at high engine speeds, the early opening
of the exhaust valves achieves better expulsion of
the exhaust gas and the late closing of the intake
valves improves cylinder charge efficiency.
Optimum power output is achieved.
Many other camshaft positions are possible in
addition to these settings.
In order to avoid a malfunction in the camshaft
adjustment units at excessively low ambient or
engine-oil temperatures, they are activated by the
PCM with a time delay via the camshaft adjustment
solenoids. The PCM receives the information
required for this from the ECT sensor and the
outside air temperature sensor.
When idling and during deceleration, the camshaft
adjustment solenoids are activated repeatedly by
the PCM in order to remove any dirt which may be
on the bore holes and ring grooves.
Boost pressure control
Optimum regulation is achieved by means of an
electronically-controlled solenoid valve, the boost
control solenoid valve.
Refer to:
Turbocharger (303-04 Fuel Charging and
Controls - Turbocharger - 2.5L Duratec
(147kW/200PS) - VI5, Description and
Operation).
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DESCRIPTION AND OPERATION
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Description
Item
Amperes
A
Volts
V
Valve rotor
1
Electronics
2
Primary coil
3
Secondary coil
4Description
Item
Analog alternating current
5
Generated PWM signal.
6
PCM
Comments:PWM signal is converted in the GEM
and forwarded via the CAN data bus.
7
The APP sensor is a double contactless inductive
sensor. The APP sensor is integrated with the
accelerator pedal in the accelerator pedal module.
The inductive sensor essentially works in a similar
way to a transformer. The incoming DC voltage
first has to be converted into AC voltage.
Depressing the accelerator pedal moves a rotor.
This induces the AC voltage from the primary coil
into the secondary coil. The strength of the
induction depends on the position of the rotor:
• no accelerator-pedal actuation: low induction, i.e. low amplitude of the AC voltage,
• full accelerator-pedal actuation: high induction, i.e., high amplitude of the AC voltage.
To allow the PCM to process the AC voltage signal
output by the secondary coil, the signal must first
be converted into a PWM signal in the sensor
electronics.
In the APP sensor the signals are split as follows:
– APP 1 = PWM signal to the GEM and from there via the CAN data bus to the PCM.
– APP 2 = the analogue DC (direct current) signal is sent directly to the PCM.
Both signals are monitored by the PCM for
plausibility.
CPP sensor
E70695
The sensor works on the Hall-effect principle and
records the position of the piston in the master
cylinder without contact. The permanent magnet
required for recording the position is located in the
piston of the clutch master cylinder.
The signal from the CPP sensor is recorded by the
GEM and transmitted to the CAN via the PCM bus.
BPP switches
E94800
The BPP switch is designed as normally-closed
contact. In its rest state the switch is closed and
sends an earth signal to the GEM.
The brake light switch is designed as
normally-open contact and is open in its rest state.
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E74168
1
23456
Description
Item
Stop screw
1
Toothed segment
2
Throttle flap spindle
3
Throttle flap return spring
4
Joint shaft
5
Electric motor with pinion
6
CAUTION: The throttle control unit must
not be repaired or adjusted. The stop of
the throttle valve must on no account be
adjusted.
If there is a fault, the throttle is returned to its
original position by means of the throttle valve
return spring. In this position, the throttle valve is
still slightly open. As a result, a higher idle speed
is set, enabling the vehicle to be driven, though
within narrow limits.
ECT sensor
E94804
The ECT sensor is designed as an NTC resistor.
A voltage of 5V is applied to the ECT sensor by
the PCM. The PCM is able to determine the coolant
temperature from the temperature-dependent
voltage drop at the sensor.
Cooling fan module
E94806
The cooling fan module is directly supplied with
battery power via a 60A fuse in the BJB. The
radiator fan speed is controlled by the PWM via a
PCM signal.
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Description
Item
Coil-on-plug ignition coil
1
Spark plug connector
2
Low-voltage connection
3
Laminated soft-iron core
4Description
Item
Primary winding
5
Secondary winding
6
Spark plug
7
High-voltage connection via spring contact
8
In an ignition system with coil-on-plug ignition coils,
each cylinder is actuated individually and only once
per cycle (working stroke). The coil-on-plug ignition
coils are mounted directly on the spark plugs,
therefore no ignition cables are required between
the ignition coils and the spark plugs.
Each individual ignition coil is actuated on the
low-voltage side by the PCM. The power
end-stages are incorporated into the coil-on-plug
ignition coils. Only the actuating current for these
power end-stages is controlled by the PCM.
Fuel pressure/fuel temperature sensor
E73531
The fuel pressure/fuel temperature sensor is a
combination of two sensors, one for the fuel
absolute pressure and one for the fuel temperature.
The sensors register the fuel values in the fuel
injection supply manifold. The sensor is supplied
with a 5V voltage by the PCM.
The fuel pressure sensor is a piezoresistor and
works using an analog signal. The change in output
voltage mirrors the change in pressure in the fuel
rail. If the pressure is low, the output voltage is also
low.
The fuel temperature sensor is an NTC resistor.
When the fuel pressure/fuel temperature sensor is
disconnected, the resistance of the fuel
temperature sensor between connections 1 and 2
of the sensor can be measured.
Resistor
Temperature
5896 Ohm
0° C
3792 Ohm
10° C
2500 Ohm
20° C
1707 Ohm
30° C
1175 Ohm
40° C
The values of the fuel pressure/fuel temperature
sensor can be read out with IDS. The displayed
values are absolute values (fuel pressure +
atmospheric pressure).
Wastegate control valve
E73539
The boost control solenoid valve is a 2/3-way valve
that is actuated with a PWM signal. This allows the
valve opening to be steplessly adjusted.
Power (battery voltage) is supplied via the
Powertrain Control Module relay in the BJB. The
solenoid coil resistance is around 23 ohms at 20°
C.
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E112323
1
2
7
6
4
5
3
10
9
11
12
Description
Item
The TSS sensor
1
The OSS sensor
2
PWM (pulse width modulation)- solenoid
valve – TCC (torque converter clutch)
(SLU)
3
PWM solenoid valve – shift pressure (SLS)
4
Shift solenoid S1
5
Shift solenoid S4
6Description
Item
Shift solenoid S3
7
Shift solenoid S5
8
Shift solenoid S2
9
The TFT (transmission fluid temperature)
sensor
10
PWM solenoid valve for main line pressure
(SLT)
11
TCM with integrated TR sensor
12
Depending on the input signals, the TCM mounted
on the transaxle actuates the solenoid valves
S1-S5 in the valve body. The solenoid valves are
either in the "open" or "closed" state.
The (SLT and SLS) control valves regulate the
hydraulic pressure according to the pulse/pause
ratio of the electrical PWM signal. The controlled
hydraulic pressure enables smooth shifting or the
generation of a defined slip through actuation of
the relevant clutches and brakes. The shift timing is calculated by the TCM using the
accelerator pedal position and vehicle speed.
Under normal conditions, gear shifting and torque
converter lockup occur at low engine speeds to
reduce fuel consumption.
If the accelerator pedal is pressed down quickly,
the TCM switches automatically into kickdown
mode.
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Automatic Transmission/Transaxle
— Vehicles With:
5-Speed Automatic Transaxle - AW55 AWD
307-01- 10
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Description
Item
ABS (anti-lock brake system)
5
Speed control
6
Select-shift switch module
7
PCM
8
Selector lever lock
9
PWM solenoid valve – shift pressure (SLS)
10
PWM solenoid valve for main line pressure
(SLT)
11
PWM- solenoid valve – TCC (SLU)
12Description
Item
Shift solenoid S1 (open when dormant)
13
Shift solenoid S2 (closed when dormant)
14
Shift solenoid S3 (closed when dormant)
15
Shift solenoid S4 (open when dormant)
16
Shift solenoid S5 (closed when dormant)
17
The TSS sensor
18
The OSS sensor
19
The TFT sensor
20
TR sensor in TCM
21
Knowing and Understanding Customer
Concerns
Knowing and understanding customer concerns is
necessary in order to perform diagnosis.
First of all, ask the customer under which operating
conditions the problem occurs. If possible, try to
reproduce the concern by road testing the vehicle
with the customer.
You should be familiar with the following operating
conditions:
• Engine operating state
– Cold, warm-up phase, or at operatingtemperature
• Ambient temperature – Below 0 °C (32 °F), 0 to 20 °C (32 to 68 °F),or above 20 °C (68 °F)
• Road conditions – Good, poor, or off-road
• Vehicle load status – Unloaded, loaded, or fully loaded
• Transaxle status in manual mode – Upshift, downshift, overrun or acceleration
Testing Possible Causes of Transmission
Control Faults
Before performing a symptom-based diagnosis,
first carry out checks to eliminate various other
potential causes of the fault.
These situations include:
• Battery state of charge
• Defective fuses • Loose or corroded cables or electrical
connectors
• Ground connections to the transmission
• Retrofitted add-on units which are not approved by Ford, such as air conditioning, car telephone,
cruise control
• Unapproved tire sizes
• Incorrect tire size programmed with IDS (Integrated Diagnostic System)
• Engine tuning
IDS Diagnosis
NOTE: Customer concerns relating to the transaxle
can also be caused by engine-related faults.
The transmission control system of the AW55 is
closely linked to the engine management system.
Faults in the engine management system may
affect the transmission control system.
Before repairing the transaxle, it should be ensured
that the fault is not caused by the engine
management system or other non-transaxle
components.
The diagnosis can be performed on the AW55 with
the aid of von IDS.
visual inspection
A thorough visual inspection of the transaxle is
necessary for successful diagnosis.
A visual inspection is made of the following
components:
• Connectors and plug connections
• Ease of operation of the selector lever
G1163604en2008.50 Kuga8/2011
307-01- 14
Automatic Transmission/Transaxle
— Vehicles With:
5-Speed Automatic Transaxle - AW55 AWD
307-01- 14
DESCRIPTION AND OPERATION
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FORD KUGA 2011.0MY WORKSHOP REPAIR MANUAL